DE69027778T2 - Coordinate processor for a computer system with a pointer arrangement - Google Patents

Description

The present invention relates generally to a coordinate processor for a computer system having a pointing device, such as a touch-sensitive screen.

Many popular computer systems, such as the IBM PS/2 Model 70 (IBM and PS/2 are trademarks of IBM Corporation), are capable of receiving and processing data generated by a pointing device, such as a mouse, trackball, or touch-sensitive screen. The pointing device enables the user of the computer system to move the position indicator (cursor) between points within a data display area of a visible display unit with a simple hand movement.

A relative displacement pointing device, such as a mouse or trackball, provides the computer system with a vector identifying the location within the data display area to which the cursor is to be moved, relative to the cursor's current location. The vector is generated by manipulating the pointing device so that a desired movement of the cursor is achieved.

An absolute position pointing device, such as a touch-sensitive screen, provides the computer system with two-dimensional coordinates that identify a point within the data display area to which the position pointer is to be moved. With a touch-sensitive screen, the coordinates are entered by touching the screen. at the point to which the position indicator should move.

Generally, relative position pointer assemblies are also provided with at least one manually operated push button. The button can be operated by the user in a variety of different ways, and the computer system can be configured to respond differently to the different modes of operation of the button. For example, the computer system can be configured to move a window of displayed data within the data display area when the button is pressed and the pointer assembly is moved. Likewise, the computer system can be programmed to perform another task when the position pointer is located within the display area on an icon representing that task and the button is pressed and released, or "clicked," in rapid succession. The computer system can be further configured to perform yet another task when the position pointer is located on an icon and the button is pressed twice, or "double-clicked."

Touch screens are not generally provided with a manually operated push button. However, a key press command can be entered on a touch screen by applying an appropriate sequence of touch stimuli to the touch screen within a predetermined period of time. An example of a virtual push button is described in US Patent No. 4,914,624. However, it must be taken into account that if the stimuli within the sequence occur at different points within the target area of the screen, then the computer system may erroneously fail to distinguish the key press command from a request to move the position indicator from one point to another. Therefore, absolute position pointer arrangements have generally been considered unsuitable for a key press command. For this reason, many commercially available application software packages have been written with relative position pointer arrays in mind. Such packages may therefore be completely or at least partially incompatible with computer systems that have an absolute position pointer array.

An object of the present invention is therefore to provide a coordinate processor that enables a computer system with an absolute position pointing arrangement to operate in the same manner as a computer system with a relative position pointing arrangement.

According to the present invention there is now provided a coordinate processor comprising: stimulus detection means for detecting a tactile stimulus of an absolute position pointer array directed to a point within a data display area of a computer system, characterized in that the processor further comprises command discrimination means responsive to the stimulus detection means for discriminating a stimulus of the pointer array to reposition a position indicator within the data display area from a stimulus of the pointer array to issue a key click command to the computer system, and including coordinate locking means for locking a current position of the position indicator at the point within the data display area corresponding to the tactile stimulus in response to said stimulus exceeding a predetermined threshold.

This advantageously enables the computer system to distinguish between position indicator movement commands and key click commands entered via an absolute position pointing arrangement without requiring a separate, manually operated push button. A user of such a computer system can therefore use application software packages developed for use with a relative position pointing arrangement. without a noticeable reduction in the performance of the computer system. More specifically, the coordinate processor enables the computer system to lock the position of the cursor at a particular coordinate when a stimulus capable of indicating a key click command is detected. However, if a key click command is not subsequently detected, the cursor is automatically unlocked.

Preferably, the coordinate locking means further comprises first reset means for enabling movement of the position indicator within the data display area upon detection of a predetermined key click command.

The coordinate locking means of a preferred embodiment of the present invention further comprises second reset means for enabling movement of the position indicator within the data display area after expiration of a predetermined time-out period.

In addition, the coordinate locking means preferably comprises third reset means for causing movement of the position indicator within the data display area upon detection of a subsequent tactile stimulus of the pointer arrangement directed to a point outside a predetermined sub-area of the data display area. The sub-area is preferably predetermined by the computer system to be in appropriate size relationship to the graphical icon generated within the data display area by the computer system.

Viewing the present invention from a second aspect, there is provided a coordinate processor comprising: stimulus detection means for detecting a stimulus of an absolute position pointer array directed to a point within a data display area defined by a computer system, characterized in that the processor further comprises: command discrimination means responsive to the stimulus detection means for discriminating a stimulus from the pointing arrangement to reposition a position indicator within the data display area from a stimulus from the pointing arrangement to issue a key click command to the computer system.

Preferably, the command discrimination means can be manually advanced to identify either a tactile stimulus of the pointing arrangement for issuing a single key click command to the computer system or to identify a tactile stimulus of the pointing arrangement for issuing a multiple key click command to the computer system.

In a preferred embodiment of the present invention, which is described below, there is provided a coordinate processor comprising: first receiving means for receiving a two-dimensional input data value from an absolute position pointer array corresponding to a point within a data display area of a computer system and generated by the pointer array responsive to a stimulus manually applied to the pointer array; second receiving means for receiving a force data value from the pointer array corresponding to the input coordinate value and generated by the pointer array in response to the stimulus; characterized in that the processor further comprises: coordinate locking means for setting a locking coordinate data value to the input coordinate data value when the force data value exceeds a predetermined threshold; Coordinate setting means for setting one or more further coordinate force data values to the lock coordinate data value if any of the further input coordinate data values falls within a predetermined range of coordinate data values within a predetermined period of time; first reset means for resetting the lock coordinate data values if at least one separate stimulus of the pointer arrangement produces a force data value that is greater than the predetermined threshold value.

A preferred embodiment of the present invention will now be described, by way of example only, with reference to the accompanying drawings, in which:

Figure 1 is a block diagram of a computer system having an absolute position pointing arrangement in the form of a touch-sensitive display screen.

Figure 2 is a block diagram of a coordinate processor of the present invention in flow chart form.

Figure 3 is a front view of a touch-sensitive screen displaying an icon within a data display area.

Figure 4 is a waveform diagram corresponding to a tactile stimulus representing a double-click command.

Figure 5 is a waveform diagram corresponding to a tactile stimulus representing a single-click command.

Figure 1 shows an example of a computer system for processing input data from an absolute position pointer array. The system includes a central processing unit (CPU) 20 for executing programmed instructions that include an input value. A bus architecture 30 communicates data between the CPU and other components of the computer system. A read-only memory (ROS) 40 provides permanent data storage. A random access memory (RAM) 50 provides temporary data storage. Data communication with other computer systems (not shown) is provided by a communications adapter (COMM) 60. An input/output (I/O) adapter 70 allows the Data communication between the bus architecture and a peripheral device such as a hard disk 80. A visible output of the computer system in the form of a data display area on a display device 110 is produced by a display adapter 120. A user may operate the computer system with a keyboard 90 connected to the bus architecture via a keyboard adapter 100. As an alternative to the keyboard 90, an absolute position pointing arrangement in the form of a touch sensitive screen 10 is superimposed over the display device 110. The touch screen 10 is responsive to a touch stimulus 130 applied by the user to issue a command to the computer system. The command may instruct the computer system to move the cursor between points in the data display area. Alternatively, the touch screen may be used to issue a key click command instructing the computer system to perform an operation corresponding to the cursor's current position in the display area.

The touch screen 10 is resolved into a two-dimensional array of discrete coordinate points by digitizing circuitry (not shown) in a pointer array adapter 140. A touch stimulus at any of the coordinate points is detected by a sensor array (not shown) in the touch screen 10. The sensor array produces an analog signal proportional to the force exerted on the touch screen by the stimulus. The signal is digitized by a sampling analog-to-digital (ADC) converter circuitry (not shown) in the touch screen (10) to produce an input data value. The input data value, along with the coordinates to which it corresponds, is transmitted from the touch screen to the pointer array adapter 140. The input data value corresponding to each set of coordinates is refreshed by the ADC circuitry typically sixty times per second. The pointer array adapter 140, which is connected to the bus architecture 30, routes each set of Coordinates and the associated input data values to the bus architecture 30.

Referring to Figure 2, a coordinate processor of the present invention distinguishes between stimuli applied to the touch screen 10 to issue a key click command and stimuli to move the cursor within the display area. It will be readily appreciated that the coordinate processor of the present invention may be implemented in a hard-wired electronic logic circuit within the adapter 140 of the pointing assembly or touch screen 10. However, in other preferred embodiments of the present invention, it may also be desirable for the coordinate processor to be in the form of a control unit, such as the CPU 20, operating under the control of a computer program.

The coordinate processor includes an input stage 200. The input stage 200 sequentially reads the sampled input data values associated with each set of coordinates (x,y)n of the touch screen 10. The coordinate processor increments a running total of key clicks BCNT each time a key click is detected. The initial value of BCNT is zero.

A count detection stage 210 checks BCNT for each input data value (x,y) received from the input stage 200. If the BCNT associated with the coordinates (x,y) is zero, then a press detection stage 280 determines whether or not the corresponding input data value has risen above a predetermined key threshold THOLD.

If no such rise is detected, the coordinates (x,y) are forwarded from the coordinate processor to the computer system to control the positioning of the position indicator within the display area. The next Input data value is then received by the input stage 200.

However, if the input data value has risen above THOLD and beyond, then a timer stage 290 sets a timeout period TIMEOUT which is equal to the current system time plus a predetermined value. In a preferred embodiment of the present invention, the timeout period can be manually set from a preset nominal average of 500 ms. Another count detection stage 300 then determines whether BCNT is zero or not.

If BCNT is zero, then a coordinate locking stage 310 sets a pair of locking coordinates (xL,yL) to the coordinates (x,y).

If BCNT is not equal to zero, the lock coordinates (xL,yL) retain their existing values. In either case, the coordinates (x,y) are then passed to the computer system to control the positioning of the position indicator. A counter 320 then increments BCNT and the next input data value (x',y') corresponding to the coordinates (x',y') is received by the input stage 200.

When the count detection stage 210 detects that BCNT for the input data value (x',y')n is greater than zero, the time measurement stage 220 indicates whether or not the time-out period has been exceeded.

If the timeout period has been exceeded, then a reset stage 270 sets BCNT to zero before (x',y')n is passed to the actuation detection stage 280.

If the time limit exceedance period has not been exceeded, then a site check level 230 checks whether the coordinates (x',y') lie outside a predetermined coordinate exclusion area AREA of the data display area or not. If the coordinates (x',y') lie outside AREA, then the reset stage 270 resets BCNT before (x',y')n is passed to the actuation detection stage 280.

If the coordinates (x',y') are within AREA, then a locking stage 240 replaces the coordinates (x',y') corresponding to the input data value (x',y')n with the locking coordinates (x'L,yL). The release detection stage 250 then detects whether or not the input data value (x',y')n has dropped below the THOLD value. If no such drop is detected, then the input data value, now corresponding to the locking coordinates (xL,yL), is passed to the actuation detection stage 280. The position of the cursor is now locked to the locking coordinates (xL,yL).

If the input data value (x',y')n has fallen below the value THOLD, then the count detection stage 260 determines whether or not BCNT is equal to a predetermined click value NCLICK.

In a particularly preferred embodiment of the present invention, NCLICK can be manually selected by the user to detect various key click commands. For example, setting NCLICK to two configures the coordinate processor 50 to detect both double click and single click commands. On the other hand, setting NCLICK to one configures the coordinate processor to detect only single click commands.

When BCNT is equal to NCLICK, the button click command has been detected. BCNT is therefore reset to zero and the input data value (x',y')n is passed to the actuation detection stage 280. The next input data value (x",y")n corresponding to the coordinates (x",y") is then received by the input stage 200.

In a preferred embodiment of the present invention, the predetermined values TIMEOUT, AREA, THOLD and NCLICK are provided to the coordinate processor by the CPU 20 under the control of an application software program. In particular, with reference to Figure 3, AREA is preferably selected to represent an area that is sized and located to match the icon 620 graphically representing a push button or the like within the data display area 610. Preferably, the computer system is configured by software so that the user can select a particular program option by issuing a click command via the touch screen 10 at the location of the icon within the display area.

Referring to Figure 4, a double-click command can be represented by the waveform 400 of a touch force applied to the touch screen 10 plotted against time. The key threshold THOLD is represented by the reference line 420. Initially, BCNT is set to zero, NCLICK is set to two, and TIMEOUT, AREA and THOLD are set to an appropriate value by the application software.

The first touch contact with the touch screen 10 occurs at time t0, with the curve 400 coinciding with the reference line 410.

At time t1, the input data value (x,y)1 at coordinates (x,y) is less than THOLD. However, at time t2, the input data value (x,y)2 at coordinates (x,y) is greater than THOLD. The actuation detection stage 280 therefore indicates that the key has been actuated and the time-out period is initialized by the timing stage 290. The lock coordinates (xL,yL) are now set for coordinates (x,y). BCNT is incremented to indicate that the position of the cursor within the display area is now locked by the lock coordinates (xL,yL). Therefore, when the next force data values (x',y')3 at time t3 and (x",y")4 at time t4 belong to coordinates (x',y') and (x",y") within the boundaries of AREA, then coordinates (x',y') and (x",y") are both replaced by the lock coordinates (xL,yL).

It is understandable that if either (x',y') or (x",y") are outside AREA, then BCNT is reset to zero and the cursor position is released.

At time t5, the data input value (x,y)5 is just greater than THOLD. At time t6, however, the data input value (x,y)6 is less than THOLD. The release detection stage 260 therefore indicates that the button has been released. However, BCNT is not equal to NCLICK. BCNT is therefore not reset to zero. Therefore, the coordinates (x',y') corresponding to the data input value (x',y')7 at time t7 are replaced by the lock coordinates (xL,yL). The cursor position is therefore still locked.

At time t8, the input data value (x',y')8 is greater than THOLD. The timeout period is therefore again initialized by the timing stage 290. BCNT is incremented to indicate that a second key click has been detected. Lock coordinates (xL,yL) remain set at the coordinates (x,y) that originally belonged to the input data value (x,y)2. The position indicator therefore remains locked at (x,y) within the display area.

At time t9, the input data value (x,y)9 is less than THOLD. The release detection stage 250 therefore indicates that the button has been released. BCNT is not equal to NCLICK, indicating that a double-click command has been detected. BCNT is now reset to zero to release the cursor position. The next touch stimulus causing an input data value greater than THOLD will therefore update the lock coordinates (xL,yL).

It is desirable and understandable that BCNT is also reset to zero if it remains at a value greater than zero for a time longer than the timeout period. Similarly, BCNT is reset to zero if an input stimulus is applied at a coordinate outside AREA.

Thus, a coordinate processor of the present invention allows the user to issue a double-click command to a computer system via a touch-sensitive screen by locking the cursor position at a position within the display area where the touch stimulus exceeds a threshold in strength. The cursor position is released when the prescribed number of clicks indicating the command is detected. Alternatively, the cursor position is released when a subsequent stimulus is applied to the touch screen outside a predetermined area of the touch screen. Furthermore, the cursor position is also released when the issue of the command is delayed for more than a predetermined time-out period. It will therefore be readily understood that the coordinate processor of the present invention freely allows the user of the computer system to move the cursor to any point within the display area at any time. Nevertheless, the coordinate processor of the present invention simultaneously allows the user to issue a key click command to the computer system via the touch screen that is independent of any cursor movement command.

Referring to Figure 5, a single click command can be represented by the waveform 500 of a touch force applied to the touch screen 10 plotted against time. The key threshold THOLD is represented by the reference line 420. Initially BCNT is set to zero, NCLICK is set to one. TIMEOUT, AREA and THOLD are set to an appropriate value by the application software.

The first touch contact with the touch screen 10 occurs at time t0, with the curve 500 coinciding with the reference line 410.

At time t1, the input data value (x,y)1 corresponding to the coordinates (x,y) is less than THOLD.

However, at time t2, the input data value (x,y)2 corresponding to the coordinates (x,y) is greater than THOLD. The operation detection stage 280 therefore indicates that the key has been operated and the time-out period is initialized by the timing stage 290. The lock coordinates (xL,yL) are now set for the coordinates (x,y) and BCNT is incremented. The position of the cursor is now locked to the coordinates (x,y).

If the coordinates (x',y') and (x",y") corresponding to the force data values (x',y')3 at time t3 and (x",y")4 at time t4 are within the boundary line of AREA, then (x',y') and (x",y") are replaced by the lock coordinates (xL,yL). The cursor position is thus locked with the coordinates (x,y).

If either (x',y') or (x",y") are outside of AREA, then BCNT is reset to zero and the next input data value that exceeds THOLD updates the lock coordinates (xL,yL) and re-locks the cursor position values.

At time t5, the data input value (x,y)5 is less than THOLD. The release detection stage 260 therefore indicates that the button has been released. BCNT is now equal to NCLICK, indicating that the single click command has been detected. BCNT is now reset to zero. Therefore, the next input Data value exceeding THOLD, refresh the lock coordinates (xL,yL).

It will now be readily understood that a coordinate processor of the present invention also enables the user of the computer system to issue a single click command to the computer system via a touch screen. In addition, a coordinate processor of the present invention also enables the user to issue a cursor movement command to the computer system via the touch screen, independent of a key click command.

More specifically, the coordinate processor of the present invention locks the cursor position at a point on the touch screen at which the applied touch stimulus has a strength that exceeds a threshold. The cursor position is released when the key click command is detected or when a subsequent stimulus is outside a predetermined area of the touch screen. The cursor position is also released when the delivery of the command is delayed for more than a predetermined time-out period. It will therefore be readily understood that the position indicator can be freely moved to any point within the display area depending on whether or not the user wishes to complete delivery of the key click command.

Curve 510 represents a continuous touch stimulus of the touch screen, first applied at time t0. BCNT is initially set to zero.

At time t1, the input data value (x,y)1 corresponding to the coordinates (x,y) is less than THOLD. However, at time t2, the input data value (x,y)2 corresponding to the coordinates (x,y) is greater than THOLD. The actuation detection stage 280 therefore indicates that the key has been actuated and the time-out period is initialized.

The lock coordinates (xL,yL) are now set for the coordinates (x,y) and BCNT is incremented. The position of the cursor is now locked with the coordinates (x,y).

At time t5, the input data value (x,y)5 is not less than THOLD. Therefore, if no stimulus outside AREA has been applied to the touch screen at time t5, BCNT is not reset. The cursor position remains locked with the coordinates (x,y).

However, at time t5' the timeout period expires. BCNT is therefore reset to zero. The cursor position is thus released. The next touch stimulus that exceeds THOLD will therefore refresh the lock coordinates (xL,yL).

A coordinate processor for a computer system having a touch-sensitive screen has been described as an example of the present invention. However, it will be readily understood that the present invention is equally applicable to other absolute position pointing arrangements, such as blackboards.

Claims (10)

1. A coordinate processor comprising: Stimulus detection means (200) for detecting a tactile stimulus of an absolute position pointer arrangement (10) directed to a point within a data display area (610) of a computer system, characterized in that the processor further comprises Command discrimination means responsive to the stimulus detection means for discriminating a stimulus from the pointing arrangement to reposition a position indicator within the data display area from a stimulus from the pointing arrangement to issue a key click command to the computer system, and including Coordinate locking means (210-320) for locking a current position of the position indicator at the point within the data display area corresponding to the tactile stimulus in response to said stimulus exceeding a predetermined threshold. 2. A processor as claimed in claim 1, wherein the coordinate locking means (210-320) further comprises first reset means (260, 270) for enabling movement of the position indicator within the data display area (610) after detection of a predetermined key click command. 3. A processor as claimed in claim 1 or claim 2, wherein the coordinate locking means (210-320) further comprise second reset means (290, 220, 270) for enabling the movement of the position indicator within the data display area (610) after the expiration of a predetermined time-out period. 4. A processor as claimed in any preceding claim, wherein the coordinate locking means (210-320) further comprises third reset means (230, 270) for enabling movement of the position indicator within the data display area (610) after detection of a subsequent tactile stimulus of the pointer arrangement (10) directed to a point outside a predetermined sub-area (600) of the data display area (610). 5. A processor as claimed in claim 4, wherein the sub-area (600) is predetermined by the computer system to be in an appropriate size relationship to the graphical icon (620) generated within the data display area (610) by the computer system. 6. A processor as claimed in any preceding claim, wherein the coordinate locking means (210-320) can be manually advanced to provide a tactile stimulus to the pointer arrangement (10) to issue a single key click command to the computer system. 7. A processor as claimed in any one of claims 1 to 5, wherein the coordinate locking means (210-320) can be manually advanced in order to identify a tactile stimulus of the pointer arrangement (10) for issuing a multiple key click command to the computer system. 8. A processor as claimed in any preceding claim, wherein the coordinate locking means (210-320) react to a digital input value which corresponds to the strength of the tactile stimulus. 9. A processor as claimed in any preceding claim, wherein the absolute pointer arrangement (10) is a touch-sensitive screen (10). 10. A computer system comprising a processor as claimed in any preceding claim.